王旭峰 研究员
1. 基本信息
 | 姓名:王旭峰 | 性别:男 |
职称:研究员 博导 | 学历:博士 | |
职务:黑河遥感站副站长 | ||
通讯地址:甘肃省兰州市城关区东岗西路320号 | ||
2. 个人简介
王旭峰,博士,中国科学院西北生态环境资源研究院研究员,博士生导师,中国科学院黑河遥感试验研究站副站长。中科院青促会会员,甘肃省杰青,陇原青年英才,科技部国家遥感中心遥感青年科技人才创新资助计划。《遥感技术与应用》、《中国草地学报》、《Research in Cold and Arid Regions》青年编委。中国遥感应用协会定量遥感专业委员会委员、中国冰冻圈科学学会青年工作委员会委员。长期开展寒旱区生态遥感、植被碳水通量观测、模拟及其对气候变化响应方面的研究,发表论文60余篇,主要研究成果发表《Nature Communications》、《Remote Sensing of Environment》、《Agricultural and Forest Meteorology》、《Earth System Science Data》等Top期刊。主持或完成了自然科学基金面上基金、青年基金、中科院青促会会员项目、青海省重大科技专项课题、重点研发计划专题、博士后特别资助等项目10余项。
3. 研究方向
生态遥感;生态模型;碳循环模型-数据融合;
4. 工作履历
2021-03 ~ 至今,中科院西北生态环境资源研究院 遥感与地理信息科学研究室,研究员(硕导);
2016-01 ~ 2021-02,中科院西北生态环境资源研究院 遥感与地理信息科学研究室,副研究员(硕导);
2015-11 ~ 2016-11,美国 University of New Hampshire, Earth System Research Center,访问学者;
2012-07 ~ 2015-12,中科院寒区旱区环境与工程研究所 遥感与地理信息科学研究室,助理研究员。
5. 教育经历
2009-09 ~ 2012-07,中科院寒区旱区环境与工程研究所,地图学与地理信息系统专业 博士;
2006-09 ~ 2009-07,中科院寒区旱区环境与工程研究所,地图学与地理信息系统专业 硕士;
2002-09 ~ 2006-07,西北师范大学 地理信息系统专业 学士。
6. 科研项目
(1)重大工程对冰冻圈要素与植被互馈机制的影响,2024 -2027,甘肃省科技重大课题。(负责人)
(2)全球变暖背景下积雪变化对高寒草地GPP的影响机制,2024 ~ 2027,国家自然科学基金委 面上基金。(负责人)
(3) 基于多源数据融合的河西绿洲碳汇潜力估算,2022-10 ~ 2024-12,甘肃省科技厅 杰出青年基金。(负责人)
(4) 高分共性产品真实性检验场站网动态规划及协同观测,2019-06 ~ 2021-06,高分重大专项(民用部分)课题。(共同负责人)
(5) 国家公园数据分析生产推送系统研发与建设,2020-06 ~ 2021-12,中科院-青海省三江源国家公园联合专项子项目。(负责人)
(6) 中国科学院青年创新促进会,2020 ~ 2023,中科院。(负责人)
(7) 基于多源观测揭示极端气候事件对青藏高原高寒草甸碳循环的影响,2018~2021,国家基金委 面上基金。(负责人)
(8)星-空-地一体化生态监测大数据平台构建及数据产品,2017~2019,青海省重大科技专项课题。(专题负责人)
(9)全球变化对生态脆弱区资源环境承载力的影响研究,2018~2022,重点研发计划课题。(参与)
(10)高寒草甸生态系统碳循环模型数据融合研究,2014~2016,国家基金委 青年基金。(负责人)
(11)博士后特别资助,2015~2017,中国博士后管理委员会。(负责人)
7. 学术兼职
《遥感技术与应用》青年编委
8. 奖励荣誉
中科院青促会
遥感青年科技人才创新资助计划
9. 学术成果(论文、专著、专利等)
发表论文:
(1) Yang Yanpeng, Wang Xufeng*, Li Zongxing, Wang Tonghong, Che Tao. Shortened Thawing and Freezing Intervals in the Northern Hemisphere Since 1990 from Sites Observations and Remote Sensing. Remote Sensing of Environment, 2025, 328: 114881.
(2) Xu Xinyao, Wang Xufeng*, Xiao Jingfeng, Zhang Songlin*, Yang Yanpeng, Li Xing, Sha Te, Li Zongxing*. Inconsistencies in global soil moisture products and discrepancies in their relationship with vegetation productivity. Journal of Hydrology, 2025, 659: 133298.
(3) Wang Xufeng, Che Tao*, Xiao Jingfeng, Wang Tonghong, Tan Junlei, Zhang Yang, Ren Zhiguo, Geng Liying, Wang Haibo, Xu Ziwei, Liu Shaomin, and Li Xin. A post-processed carbon flux dataset for 34 eddy covariance flux sites across the Heihe River Basin, China. Earth System Science Data, 2025, 17, 1329–1346. https://doi.org/10.5194/essd-2024-370.
(4) Wang Tonghong, Wang Xufeng*, Zhang Qiang, Zhang Songlin *, Tan Junlei, Zhang Yang, Ren Zhiguo, Yang Yanpeng, Che Tao. Effects of extreme temperature events on carbon fluxes in different ecosystems in the Heihe River Basin, China. Agricultural and Forest Meteorology, 2025, 362: 110380.
(5) Wei Yanqiang, Jing Li, Dongliang Luo, Xuejie Tang, Zihao Wu, Xufeng Wang*, Risks and sustainability of outdoor ski resorts in China under climate changes, npj Climate and Atmospheric Science, 2025,8:26, https://doi.org/10.1038/s41612-025-00917-0.
(6) Zhou Xuqiang, Wang Xufeng*, Ren Zhiguo, Zhang Yang, Tan Junlei, Zain. Human activities rather than climate change dominate the growth of carbon fluxes in the Hexi Cohhidor oasis area, China. Journal of Geographical Sciences, 2025, 35: 252–272.
(7) Ge ZX, Huang J, Wang XF*, Tang XG, Fan L, Zhao YJ, Ma MG*. Contrasting trends between peak photosynthesis timing and peak greenness timing across seven typical biomes in Northern Hemisphere mid-latitudes. Agricultural and Forest Meteorology, 2022, 323: 109054.
(8) Zhu GF#, Wang XF#, Xiao JF#, Zhang K, Wang YQ, He HL, Li WD, Chen HL. Daytime and nighttime warming has no opposite effects on vegetation phenology and productivity in the northern hemisphere. Science of the Total Environment, 2022, 822: 153386.
(9) Wang XF, Xiao JF, Li X, Cheng GD, Ma MG, Zhu GF, Arain MA, Black TA, Jassal RS. No trends in spring and autumn phenology during the global warming hiatus. Nature Communications, 2019, 10:2389, doi: 10.1038/s41467-019-10235-8. (SCI; Impact Factor = 11.880)
(10) Wang XF, Xiao JF, Li X, Cheng GD, Ma MG, Che T, Dai LY, Wang SY, Wu JK. No Consistent Evidence for Advancing or Delaying Trends in Spring Phenology on the Tibetan Plateau. Journal of Geophysical Research: Biogeosciences, 2017, 122, 3288-3305.
(11) Wang XF, Cheng GD, Li X, Ma MG, Lu L, Su PX, Zhu GF, A comparison of two photosynthesis parameterization schemes for an alpine meadow site on the Qinghai-Tibetan Plateau, Theoretical and Applied Climatology, 2016, 126:751–764.
(12) Wang XF, Cheng GD, Li X, Lu L, Ma MG, An Algorithm for Gross Primary Production (GPP) and Net Ecosystem Production (NEP) Estimations in the Midstream of the Heihe River Basin, China. Remote Sensing, 2015, 7(4), 3651-3669.
(13) Wang XF, Ma MG, Song Y, Tan JL, Wang H, Coupling of a biogeochemical model with a simultaneous heat and water model and its evaluation at an alpine meadow site. Environmental Earth Sciences, 2014, 72(10), 4085-4096.
(14) Wang XF, Ma MG, Li X, Song Y, Tan JL, Huang GH, Zhang ZH, Zhao TB, Feng JM, Ma ZG, Wei W, Bai YF. Validation of MODIS GPP product at ten flux sites in northern China. International Journal of Remote Sensing, 2013, 34:2,587-599.
(15) Wang XF, Ma MG, Huang GH, Veroustraete F, Zhang ZH, Song Y, Tan JL. Vegetation Primary Production Estimation at Maize and Alpine Meadow over the Heihe River Basin, China. International Journal of Applied Earth Observations and Geoinformation. 2012. 17: 94-101.
(16) Wang XF, Ma MG, Li X, Han XJ, Ran YH, Huang GH, Song Y, Tan JL. GPP estimation over Heihe River Basin, China. Proceedings of SPIE Vol. 8174, 817422 (2011).
(17) Wang XF, Ma MG, Han XJ, Song Y. Assimilation of soil moisture in LPJ-DGVM. Proc. of SPIE Vol. 7472, 747220 (2009).
(18) Wei W, Pang SF*, Wang XF*, Zhou L, Xie BB, Zhou JJ, and Li CH. 2020. Temperature Vegetation Precipitation Dryness Index (TVPDI)-based dryness-wetness monitoring in China. Remote Sensing of Environment 248:111957.
(19) Zhou XQ; Wang XF*; Zhang, S.; Zhang, Y.; Bai, X. Combining Phenological Camera Photos and MODIS Reflectance Data to Predict GPP Daily Dynamics for Alpine Meadows on the Tibetan Plateau. Remote Sensing. 2020, 12, 3735.
(20) Wei D, Zhao H, Wang XF, GaoYH, Wang XD*. Reply to Ma and Zuo: Ecological restoration on the Tibetan Plateau would benefit tehhestrial CO2 uptake, Proceedings of the National Academy of Sciences, 2022, 119, 5.
(21) Wei D, Qi YH, Ma YM, Wang XF, Ma WQ, Gao TG, Huang L, Zhao H, Zhang JX., Wang XD*. Plant uptake of CO2 outpaces losses from permafrost and plant respiration on the Tibetan Plateau. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118(33): e201528311.
(22) 王同红,王旭峰*,张松林*,谭俊磊,张阳,任志国,白雪洁. 寒旱区内陆河流域碳通量年际变化控制机制. 地球科学,2024(待刊)
(23) 白雪洁,王旭峰*,柳晓惠,周旭强. 黑河流域湿地、农田、草地生态系统碳通量变化特征及驱动因子分析. 遥感技术与应用, 2022, 37(1):94-107.
